Sven Grashey-Jansen, Martin Kuba, Bernd Cyffka, Ümüt Halik, Tayierjiang Aishan. Spatio-temporal Variability of Soil Water at Three Seasonal Floodplain Sites: A Case Study in Tarim Basin, Northwest China[J]. Chinese Geographical Science, 2014, (6): 647-657. doi: 10.1007/s11769-014-0717-y
Citation: Sven Grashey-Jansen, Martin Kuba, Bernd Cyffka, Ümüt Halik, Tayierjiang Aishan. Spatio-temporal Variability of Soil Water at Three Seasonal Floodplain Sites: A Case Study in Tarim Basin, Northwest China[J]. Chinese Geographical Science, 2014, (6): 647-657. doi: 10.1007/s11769-014-0717-y

Spatio-temporal Variability of Soil Water at Three Seasonal Floodplain Sites: A Case Study in Tarim Basin, Northwest China

doi: 10.1007/s11769-014-0717-y
Funds:  Under the auspices of Federal Ministry of Education and Research of Germany Project-Sustainable Management of River Oases along the Tarim River (No. 01LL0918D), National Natural Science Foundation of China (No. 31270742, 31360200)
  • Received Date: 2013-10-23
  • Rev Recd Date: 2014-02-21
  • Publish Date: 2014-09-27
  • The floodplain vegetation of the Tarim River in Northwest China is strongly influenced by irrigated agriculture. The abstraction of river water disturbs the natural dynamics of the floodplain ecosystem. The human impact on the hydrological system by bank dams and the irrigation of cotton plantings have caused adverse changes of the Tarim River and its floodplains, so the current stocks of the typical Tugai vegetation show significant signs of degradation. Field studies of soils and statistical analysis of soil moisture data have shown that the vitality of the Tugai vegetation is primarily determined by its position to the riverbank and the groundwater. There exist complex interactions between soil hydrological conditions and the vitality of the vegetation. But the availability of water is not only influenced by the groundwater level and seasonal flood events. The spatial distribution of stocks at different states of vitality seems also to be decisively influenced by physical soil properties. Our results show that the water supply of plant communities is strongly influenced by the soil texture. Spatial differences of soil moisture and corresponding soil water tensions may be the decisive factors for the zonation of vegetation. Physical soil properties control the water retention and rising of capillary water from deeper soil layers and the phreatic zone and may supply the root systems of the phreatophytic vegetation with water.
  • [1] Aishan T, Halik Ü, Cyffka B et al., 2013. Monitoring the hydrological and ecological response to water diversion in the lower reaches of the Tarim River, Northwest China. Quaternary International, 311: 155-162. doi:  10.1016/j.quaint.2013.08.006
    [2] Aishan T, Halik Ü, Kurban A et al., 2014. Eco-morphological response of floodplain forests (Populus euphratica Oliv.) to water diversion in the lower Tarim River, Northwest China. Environmental Earth Science, 1-13. doi: 10.1007/s12665- 013-3033-4.
    [3] Breshears D D, Myers O, Barnes F J, 2009. Horizontal heterogeneity in the frequency of plant-available water with woodland intercanopy-canopy vegetation patch type rivals that occurring vertically by soil depth. Ecohydrology, 2(4): 503-519. doi:  10.1002/eco.75
    [4] Chen F H, Huang X Z, Zhang J W et al., 2006. Humid Little Ice Age in arid central Asia documented by Bosten Lake, Xinjiang, China. Science in China (Series D), 49(12): 1280-1290. doi:  10.1007/s11430-006-2027-4
    [5] Chen Xiaobing, Yang Jinsong, Liu Chunqing, 2007. Study on soil secondary salinization and related issues in Alar Irrigation Area, Xinjiang. Journal of Arid Land Resources and Environment, 21(6): 168-172. (in Chinese)
    [6] Chen Y J, Chen Y N, Liu J Z et al., 2009. Influence of intermittent water releases on groundwater chemistry at the lower reaches of the Tarim River, China. Environmental Monitoring and Assessment, 158(1-4): 251-264. doi: 10.1007/s10661- 008-0579-9
    [7] Chen Y N, Chen Y P, Xu C C et al., 2010. Effects of ecological water conveyance on groundwater dynamics and riparian vegetation in the lower reaches of Tarim River, China. Hydrological Processes, 24(2): 170-177. doi:  10.1002/hyp.7429
    [8] Chen Y N, Xu C C, Chen Y P et al., 2013. Progress, challenges and prospects of eco-hydrological studies in the Tarim River Basin of Xinjiang, China. Environmental Management, 51(1): 138-153. doi:  10.1007/s00267-012-9823-8
    [9] Chen Y, Takeuchi K, Xu C et al., 2006. Regional climate change and its effects on river runoff in the Tarim Basin, China. Hydrological Processes, 20(10): 2207-2216.
    [10] Chen Y, Xu Z, 2005. Plausible impact of global climate change on water resources in the Tarim River Basin. Science in China (Series D: Earth Sciences), 48(1): 65-73. doi:  10.1360/04yd0539
    [11] Daly E, Porporato A, 2005. A review of soil moisture dynamics: From rainfall infiltration to ecosystem response. Environmental Engineering Science, 22(1): 9-24. doi:  10.1089/ees.2005.22.9
    [12] Ehlers W, Goss M, 2003. Water Dynamics in Plant Production. Cambridge: CABI Publishing, 273.
    [13] Fu A H, Chen Y N, Li W H, 2006. Analysis on water potential of populus euphratica oliv and its meaning in the lower reaches of Tarim River, Xinjiang. Chinese Science Bulletin, 51(1): 221-228. doi:  10.1007/s11434-006-8229-5
    [14] Giese E, Mamatkanov D M, Wang R, 2005. Water Resources and Water Use in the Tarim River Basin (Autonomous Region Xinjian/China). Center for International Development and Environmental Research of the Justus-Liebig-University Gießen (Germany), 25.
    [15] Grashey-Jansen S, 2014. Irrigation efficiency under a flat rate sprinkler system on heterogeneous soils­-A pedotransfer- based comparison. International Journal of Geology, Agriculture and Environmental Sciences, 2(1): 8-15.
    [16] Grashey-Jansen S, Timpf S, 2010. Soil hydrology of irrigated orchards and agent-based simulation of a soil dependent precision irrigation system. Advanced Science Letters, 3(3): 259-272. doi:  10.1166/asl.2010.1124
    [17] Gui D, Lei J, Mu G et al., 2009. Effects of different management intensities on soil quality of farmland during oasis development in southern Tarim Basin, Xinjiang, China. International Journal of Sustainable Development & World Ecology, 16(4): 295-301. doi:  10.1080/13504500903108887
    [18] Hai Y, Wai L, Hoppe T et al., 2006. Half a century of environmental change in the Tarim River Valley-An outline of cause and remedies. In: Hoppe T et al. (eds.). Watershed and Floodplain Management along the Tarim River in China's Arid Northwest. Aachen: Shaker Press, 39-76.
    [19] Halik Ü, Küchler J, Kleinschmitt B, 2005. Before planet Earth turns into a desert. TU International, 57(3): 34-37.
    [20] Halik Ü, Kurban A, Chai Z et al., 2009. The positive response of some ecological indices of Populus euphratica to the emergency water transfer in the lower reaches of the Tarim River. Resources Science, 31(8): 1309-1314.
    [21] Halik Ü, Kurban A, Mijit M et al., 2006. The potential influence of embankment engineering and ecological water transfers on the riparian vegetation along the middle and lower reaches of Tarim River. In: Hoppe T et al. (eds.). Watershed and Floodplain Management along the Tarim River in China's Arid Northwest. Aachen: Shaker Press, 221-236.
    [22] Hao X M, Chen Y N, Li W H, 2009. Indicating appropriate groundwater tables for desert river-bank forest at the Tarim River, Xinjiang,China. Environmental Monitoring Assessment, 152(1-4): 167-177. doi:  10.1007/s10661-008-0305-7
    [23] Hu S J, Zhao R F, Tian C Y et al., 2009. Empirical models of calculating phreatic evaporation from bare soil in Tarim River Basin, Xinjiang. Environmental Earth Science, 59(3): 663- 668. doi:  10.1007/s12665-009-0063-z
    [24] Huang T M, Pang Z H, 2010. Changes in groundwater induced by water diversion in the Lower Tarim River, Xinjiang Uygur, NW China: Evidence from environmental isotopes and water chemistry. Journal of Hydrology, 387(3-4): 188-201. doi:  10.1016/j.jhydrol.2010.04.007
    [25] Ishizuka M, Mikami M, Yamada Y et al., 2005. An observational study of soil moisture effects on wind erosion at a gobi site in the Taklimakan Desert. Journal of Geophysical Research: Atmospheres (1984-2012), 110(D18): 1-10. doi: 10.1029/2004 JD004709
    [26] Ji Fang, Ma Yingjie, Fan Zili, 2001. Soil water regime in Populus euphratica forest on the Tarim River Alluvial Plain. Acta Phytoecological Sinica, 25(1): 17-21. (in Chinese)
    [27] Jin Z Z, Lei J Q, Xu X W et al., 2008. Evaluation of soil fertility of the shelter-forest land along the Tarim Desert Highway. Chinese Science Bulletin, 53(2): 125-136. doi:  10.1007/s11434-008-6015-2
    [28] Kuba M, Aishan T, Cyffka B et al., 2013. Analysis of connections between soil moisture, groundwater level and vegetation vitality along two transects at the lower reaches of the Tarim River, Northwest China. Geo-Oeko, 34(1-2): 103-128.
    [29] Liu G, Kurban A, Duan H et al., 2014. Desert riparian forest colonization in the lower reaches of Tarim River based on remote sensing analysis. Environmental Earth Science, 71(10): 4579-4589. doi:  10.1007/s12665-013-2850-9
    [30] Liu W G, Liu Z H, An Z S et al., 2010. Wet climate during the 'Little Ice Age' in the arid Tarim Basin, northwestern China. The Holocene, 21(3): 409-416. doi:  10.1177/0959683610378881
    [31] Ma X D, Chen Y N, Zhu C G et al., 2011. The variation in soil moisture and the appropriate groundwater table for desert riparian forest along the Lower Tarim River. Journal of Geographical Sciences, 21(1): 150-162. doi: 10.1007/s11442- 011-0835-8
    [32] Miller G, Cable J M, Mcdonald A K et al., 2011. Understanding ecohydrological connectivity in savannas: A system dynamics modelling approach. Ecohydrology, 5(2): 200-220. doi:  10.1002/eco.245
    [33] Nijland W, Meijde M V, Addink E A et al., 2010. Detection of soil moisture and vegetation water abstraction in a Mediterranean natural area using electrical resistivity tomography. Catena, 81(3): 209-216. doi:  10.1016/j.catena.2010.03.005
    [34] Pei Z Q, Xiao Chu W, Dong D et al., 2011. Comparison of the fine root dynamics of Populus euphratica forests in different habitats in the lower reaches of Tarim River in Xingjiang, China, during the growing season. Journal of Forest Research, 17(4): 343-351. doi:  10.1007/s10310-011-0299-9
    [35] Rodriguez-Iturbe I, Porporato A, 2004. Ecohydrology in Water-controlled Ecosystems: Soil Moisture and Plant Dynamics. Cambridge: Cambridge University Press, 440.
    [36] Schickhoff U, 2011. Biogeographical distributions: The role of past environments, physical factors and biotic interactions. In: Millington A C et al. (eds.). Handbook of Biogeography. London: Sage Publications, 141-169.
    [37] Schulz H, Hartling S, 2003. Vitality analysis of Scots pines using a multivariate approach. Forest Ecology and Management, 168: 73-84.
    [38] Shi Y, Shen Y, Kang E et al., 2007. Recent and future climate change in Northwest China. Climatic Change, 80(3-4): 379- 393.
    [39] Song Yudong, Fan Zili, Lei Zhidong et al., 2000. Research on Water Resources and Ecology of Tarim River, China. Urumqi: Xinjiang People's Press, 378. (in Chinese)
    [40] Tang Q C, Chen H Y, 1992. Water resources and oasis construction in Tarim Basin. Chinese Geographical Science, 2(2): 173-182. doi:  10.1007/BF02664539
    [41] Tao H, Gemmer M, Bai Y et al., 2011. Trends of streamflow in the Tarim River Basin during the past 50years: Human impact or climate change? Journal of Hydrology, 400(1): 1-9.
    [42] Tashi Y, Chamard P C, Courel M F et al., 2010. The recent evolution of the oasis environment in the Talimakan Desert, China. In: Schneier-Madanes G et al. (eds.). Water and Sustainability in Arid Region-Bridging the Gap Between Physical and Social Sciences. Berlin: Springer, 51-74.
    [43] Thevs N, Zerbe S, Peper J et al., 2008a. Vegetation and vegetation dynamics in the Tarim River floodplain of continental-arid Xinjiang, NW China. Phytocoenologia, 38(1-2): 65-84. doi:  10.1127/0340-269X/2008/0038-0065
    [44] Thevs N, Zerbe S, Schnittler M et al., 2008b. Structure, reproduction and flood-induced dynamics of riparian Tugai forests at the Tarim River, Xinjiang, NW China. Forestry, 81(1): 45-57. doi:  10.1093/forestry/cpm043
    [45] Turnbull L, Wainwright J, Brazier R E, 2010. Changes in hydrology and erosion over a transition from grassland to shrubland. Hydrological Processes, 24(4): 393-414. doi: 10.1002/hyp. 7491
    [46] Walter H, 1974. The Vegetation of Eastern Europe, Northern and Central Asia. Stuttgart: Gustav Fischer Publishing, 452.
    [47] Wang S J, Chen B H, Li H Q, 1996. Euphrates Poplar Forest. Beijing: China Environmental Science Press, 212.
    [48] Wang X M, Dong Z B, Zhang J W et al., 2002. Geomorphology of sand dunes in the Northeast Taklimakan Desert. Geomorphology, 42(3-4): 183-195.
    [49] Wei Z, 1996. Surface water chemical changes due to human activities in the Tarim Basin. GeoJournal, 40(1-2): 25-29. doi:  10.1007/BF00222527
    [50] Westermann J, Zerbe S, Eckstein D, 2008. Age structure and growth of degraded Populus euphratica floodplain forests in Northwest China and perspectives for their recovery. Journal of Integrative Plant Biology, 50(5): 536-546. doi:  10.1111/j.1744-7909.2007.00626.x.
    [51] Wu X Q, Cai Y L, 2004. Land cover changes and landscape dynamics assessment in lower reaches of Tarim River in China. Chinese Geographical Science, 14(1): 28-33. doi:  10.1007/s11769-004-0005-3
    [52] Xu H L, Ye M, Song Y D, 2005. The dynamic variation of water resources and its tendency in the Tarim River Basin. Journal of Geographical Sciences, 15(4): 467-474. doi:  10.1007/BF02892154
    [53] Zerbe S, Thevs N, 2011. Restoring central Asian floodplain ecosystems as natural capital and cultural heritage in a continental desert environment. In: Hong S K et al. (eds.). Landscape Ecology in Asian Cultures. Berlin: Springer, 277-297.
    [54] Zhang F, Tiyip T, Ding J L et al., 2013. Studies on the reflectance spectral features of saline soil along the middle reaches of Tarim River: A case study in Xinjiang Autonomous Region, China. Environmental Earth Science, 69(8): 2743-2761. doi:  10.1007/s12665-012-2096-y
    [55] Zhang Q, Xu C Y, Tao H et al., 2010. Climate changes and their impacts on water resources in the arid regions: A case study of the Tarim River Basin, China. Stochastic Environmental Research and Risk Assessment, 24(3): 349-358.
    [56] Zhang Y M, Chen Y N, Pan B R, 2005. Distribution and floristics of desert plant communities in the lower reaches of Tarim River, southern Xinjiang, People's Republic of China. Journal of Arid Environments, 63(4): 772-784.
    [57] Zhao R F, Chen Y N, Li W H et al., 2009. Land cover change and landscape pattern in the mainstream of the Tarim River. Acta Geographica Sinica, 64(1): 95-106.
    [58] Zhou J L, Li G M, Liu F et al., 2009. DRAV model and its application in assessing groundwater vulnerability in arid area: A case study of pore phreatic water in Tarim Basin, Xinjiang, Northwest China. Environmental Earth Science, 60(5): 1055-1063. doi:  10.1007/s12665-009-0250-y
    [59] Zhou Q M, Li B L, Kurban A, 2008. Spatial pattern analysis of land cover change trajectories in Tarim Basin, Northwest China. International Journal of Remote Sensing, 29(19): 5495-5509. doi:  10.1080/01431160802060938
    [60] Zhu Z, Chen G, 1994. Sandy Desertification in China. Beijing: Science Press, 110.
    [61] Zhuang L, Chen Y N, Li W H et al., 2007. Responses of Tamarix ramosissima ABA accumulation to changes in groundwater levels and soil salinity in the lower reaches of Tarim River, China. Acta Ecologica Sinica, 27(10): 4247-4251. doi:  10.1016/S1872-2032(07)60090-0
    [62] Zhuang L, Dong Y S, Yin F H et al., 2010. Historical evolution and the effects of ecological management in Tarim Basin, China. Chinese Science Bulletin, 55(36): 4097-4103. doi:  10.1007/s11434-010-4252-7
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Spatio-temporal Variability of Soil Water at Three Seasonal Floodplain Sites: A Case Study in Tarim Basin, Northwest China

doi: 10.1007/s11769-014-0717-y
Funds:  Under the auspices of Federal Ministry of Education and Research of Germany Project-Sustainable Management of River Oases along the Tarim River (No. 01LL0918D), National Natural Science Foundation of China (No. 31270742, 31360200)

Abstract: The floodplain vegetation of the Tarim River in Northwest China is strongly influenced by irrigated agriculture. The abstraction of river water disturbs the natural dynamics of the floodplain ecosystem. The human impact on the hydrological system by bank dams and the irrigation of cotton plantings have caused adverse changes of the Tarim River and its floodplains, so the current stocks of the typical Tugai vegetation show significant signs of degradation. Field studies of soils and statistical analysis of soil moisture data have shown that the vitality of the Tugai vegetation is primarily determined by its position to the riverbank and the groundwater. There exist complex interactions between soil hydrological conditions and the vitality of the vegetation. But the availability of water is not only influenced by the groundwater level and seasonal flood events. The spatial distribution of stocks at different states of vitality seems also to be decisively influenced by physical soil properties. Our results show that the water supply of plant communities is strongly influenced by the soil texture. Spatial differences of soil moisture and corresponding soil water tensions may be the decisive factors for the zonation of vegetation. Physical soil properties control the water retention and rising of capillary water from deeper soil layers and the phreatic zone and may supply the root systems of the phreatophytic vegetation with water.

Sven Grashey-Jansen, Martin Kuba, Bernd Cyffka, Ümüt Halik, Tayierjiang Aishan. Spatio-temporal Variability of Soil Water at Three Seasonal Floodplain Sites: A Case Study in Tarim Basin, Northwest China[J]. Chinese Geographical Science, 2014, (6): 647-657. doi: 10.1007/s11769-014-0717-y
Citation: Sven Grashey-Jansen, Martin Kuba, Bernd Cyffka, Ümüt Halik, Tayierjiang Aishan. Spatio-temporal Variability of Soil Water at Three Seasonal Floodplain Sites: A Case Study in Tarim Basin, Northwest China[J]. Chinese Geographical Science, 2014, (6): 647-657. doi: 10.1007/s11769-014-0717-y
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